KR200278585Y1 - Bio room - Google Patents

Abstract

The present invention is to apply bioglass, a new material that emits far infrared rays and anions at low temperature, to the floor, wall, and ceiling, but the coating plate is installed on the wall with a certain distance from the wall, and heated by heating means on the back surface from the bioglass The present invention relates to a bio-room that can be used for a long time by installing far infrared rays and negative ions, and is simple in structure, easy to install, and low in facility cost, and easy to repair and replace in case of failure or damage.

Bio-room according to the present invention is installed on the inside wall wall heating means for emitting heat; An inner wall coated with bioglass which is heated by the wall heating means and generates far infrared rays and anions; Floor heating means installed on the floor to heat the floor; And a bottom coated with a top surface of the bioglass which is heated by the bottom heating means to generate far infrared rays and anions.

Description

Bio room

The present invention relates to a bioroom that releases far-infrared rays, which are beneficial to the human body, to relieve fatigue and improve health. More specifically, bioglass, a new material that emits far-infrared rays and anions at low temperatures, is applied to floors, walls, and ceilings. However, the coating plate is installed on the wall spaced apart from the wall by a certain distance, and heated by heating means on the back to release far-infrared rays and anions from the bioglass. The present invention relates to a bio-room that is easy to install and inexpensive to install, as well as easy to replace and repair in case of failure or damage.

With the rapid development of industrial society and the improvement of living standards, interest in health is increasing day by day. Accordingly, in recent years, various jjimjilbangs are becoming popular for fatigue recovery, stress relief, weakness constitution, weight loss, pain relief and disease prevention.

These jjimjilbangs usually use the far-infrared radiation materials such as ocher, elvan, jade and germanium to directly and indirectly obtain the effects and effects of the far-infrared rays emitted from them, thereby increasing the metabolism and promoting the blood circulation to promote human health. have.

Far infrared rays are a kind of electromagnetic waves with a large thermal effect due to the longer wavelength than the red region of visible light. They are well absorbed by materials and have strong resonance and resonance effects on organic compound molecules. Therefore, far-infrared rays are absorbed by skin well and penetrate deeply (about 40 ~ 70mm) to make heat, which helps to eliminate bacteria that cause various diseases, and expands capillaries to create blood circulation and tissue Will contribute to In addition, by touching the water and protein molecules constituting the cell shakes the cell more than 2000 times per minute to activate the cell tissue has excellent effects in preventing various adult diseases such as aging, promoting metabolism, chronic fatigue. In addition, it promotes sweating, pain relief, heavy metal removal, sleep, deodorization, antibacterial, mold propagation prevention, dehumidification, air purification.

However, the effect of the poultice in the jjimjilbang radiating such beneficial far-infrared rays is slightly different depending on the users, but the effect is only minimal, and the method of directly directing the far-infrared rays radiated by high heat is selected. As a result, the efficiency of the far-infrared experience is not only difficult to obtain as expected, and the steaming is performed around the high heat generating element, so that the risk of burn is always exposed.

Recently, the jjimjilbang using sand or the jjimjilbang using weak stones have emerged, but this also obtains the treatment effect by the above-mentioned far-infrared radiation in a different way, and the sand bath which can only be done on the beach in summer season is limited. The convenience and versatility of being able to use indoors without regard to convenience can be obtained, and no special technology can be provided that directly affects treatment and health.

In the jjimjilbang discussed above, the materials that emit far infrared rays are natural materials, that is, elvan, ocher, jade, amethyst, etc., and thus the amount of far infrared rays emitted is rapidly decreased as time passes. In more detail, in the case of radiating far infrared rays by heating the above-mentioned natural material at a high temperature, the radiation dose of far infrared rays is remarkably reduced after about 6 months to 1 year, and in order to emit far infrared rays At higher temperatures, harmful gases may be released. Therefore, it may be harmful to the human body, and after a certain period of time, there is a problem that expensive maintenance costs are required because the exhausted natural material needs to be re-installed as a new wall after removing the wall equipped with the concrete structure. In addition, there is a disadvantage that there is a concern of side effects when a large amount of high-temperature heat energy to the weak or the elderly.

Therefore, the object of the present invention is to solve the above-mentioned drawbacks, it is possible to operate at a low temperature because it is composed of bioglass, which is a new material that emits far infrared rays and anions even at low temperatures, respectively applied to the floor, wall, and ceiling. Therefore, there is no frustration even when used for a long time, and to provide a bio room that can prevent burns or other injuries due to high heat.

In addition, another object of the present invention is to install the bioglass coated steel sheet spaced apart from the wall at a predetermined distance and to heat the wall heating means on the back to install far infrared and negative ions from the bioglass, the structure is simple and easy to install In addition to the low cost of the facility, it is to provide a bioroom that is easy to replace and repair in case of failure or damage.

DETAILED DESCRIPTION A detailed description of embodiments of the present invention will be made with reference to the accompanying drawings, in which like numbers designate corresponding parts in the drawings.

1 is a block diagram showing the inside of the bioroom according to the present invention from the side,

2 is a cross-sectional view taken along the line A-A of Figure 1 showing the inside of the bioroom according to the present invention,

3 is a view showing a floor structure of the bioroom according to the present invention,

Figure 4 is a perspective view schematically showing the interior of the present bioroom.

** Explanation of symbols for main parts of drawings **

10 brick 12 insulation

14: tin 20: bioglass coated steel sheet

22: reinforcing material 24: asbestos mesh material

26: bioglass layer 30: coating plate support member

32: first vertical stiffener 34: first horizontal stiffener

40: steam pipe 50: steam pipe support member

52: second vertical stiffener 54: second horizontal stiffener

60: concrete floor 62: insulation

64: wire mesh 70: hot water pipe

80: mortar 82: bioglass layer

84: sheet plate 90: ceiling plate

92: bioglass layer

Bio-room according to the present invention for achieving the above object is a wall surface heating means for dissipating heat is installed inside the wall; An inner wall coated with bioglass which is heated by the wall heating means and generates far infrared rays and anions; Floor heating means installed on the floor to heat the floor; And a bottom on which the bioglass, which is heated by the bottom heating means and generates far infrared rays and anions, is coated on the upper surface.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to a preferred embodiment of the present invention.

1 is a schematic view showing the inside of the bioroom according to the present invention from the side, Figure 2 is a cross-sectional view taken along line AA of Figure 1 showing the inside of the bioroom according to the present invention, Figure 3 according to the present invention The figure shows the floor structure of the bioroom. 4 is a perspective view schematically showing the interior of the present bioroom. The construction structure of the bioroom of the present invention will be described in detail with reference to the drawings.

As shown in the figure, after the heat insulating material 12 is interposed in the inner wall of the brick 10 layered by cement brick stacking, the tin 14 is attached to the inside thereof to form a wall. The bioglass-coated steel sheet 20 is fixed to the inside of the wall 14 of the wall structure thus constructed with a coating plate support member 30 spaced apart from the wall by a predetermined distance. The coated plate support member 30 is attached to upper and lower portions of the first vertical stiffeners 32 which are in close contact with the inner wall of the tin 14 and are installed in the vertical direction. 20 and the first horizontal reinforcement 34 is respectively coupled to the upper and lower ends.

In this way, the bioglass coated steel sheet 20 is heated between the bioglass coated steel sheet 20 and the tin 14 which are installed at a predetermined interval from the wall by the coating plate support member 30 to emit far infrared rays and anions from the bioglass. Wall heating means are provided. The wall heating means is a steam pipe 40 for discharging steam, and a steam pipe support member 50 is provided on the inner surface of the tin 14 to support the steam pipe 40 at a predetermined interval from the wall surface. The steam pipe support member 50 is attached to the upper and lower portions of the second vertical reinforcement 52 fixed to the inner surface of the tin 14 in the vertical direction, and grips the steam pipe 40. The second horizontal reinforcing material 54 is being made. By the steam flowing through the steam pipe 40, the bioglass coated steel plate 20 located in front thereof is heated, and far infrared rays and anions are released from the bioglass.

Bioglass is a patented application as a new composition rather than a natural material. To explain roughly, mineral powders such as stone powder, feldspar, borax and boric acid are the main raw materials, alumina, sodium oxide and barium are the main raw materials, and the main raw materials, the subsidiary materials and the additives are mixed in powder or granule and then at 1,350 ~ 1,500 ° C. It is produced by heating until it is completely melted (vitrified), molded into various forms suitable for the use used by the slow cooling method, or molded into powder or granular form by quenching and mechanical grinding methods. The far-infrared radiation energy of the bioglass manufactured through this process is characterized by the emission of far-infrared radiation with high emissivity (0.93) at 3.54 × 10 ² (W / ㎡, ㎛), which is known to be the most beneficial to our body. As such, bioglass is a material that emits large amounts of far infrared rays and anions, and is a semi-permanent material whose properties do not change even after long-term use. Accordingly, the radiation of far infrared rays and anions is excellent, and the radiation efficiency of far infrared rays is good at a temperature of about 40 ° C. (40-50 ° C.) rather than high temperature. Therefore, this bioroom emits far-infrared rays and anions while maintaining a slightly higher temperature than normal temperature rather than high temperature, so that there is no burn or cramping in use. Moreover, even if the haptic temperature is low, heat is transmitted up to 4-5 mm in the skin by the far-infrared effect, so that the effect of ejecting sweat or waste products is high.

On the other hand, the above-described bioglass coated steel sheet 20 is coupled to the first horizontal reinforcing material 34 is coupled to the reinforcing materials 22 on the back. Asbestos mesh material 24 is attached to the front surface of the bioglass coated steel sheet 20 so that the bioglass does not crack, and the bioglass is coated thereon to form the bioglass layer 26. It is preferable to apply the bioglass in at least two or more layers, and if more intense far infrared rays are desired, the bioglass layer 26 may be thickened by applying more layers. Of course, the bioglass can always be kept in the best state by easily painting on it when the far-infrared effect is reduced. The above bioglass coated steel sheet 20 and asbestos mesh material 24 can be seen as the inner wall, in which case it can be said that the steam pipe 40 as a wall heating means is built in the wall.

Bioglass is also applied to the bottom to release far infrared rays and anions. To this end, the insulating material 62 is laminated on the existing concrete floor 60, and then the hot water pipe 70, which is a floor heating means, is covered with the wire mesh 64 thereon. The pipe piped in this way is covered with a mortar (80) to flatten the bottom. Then, the bioglass is coated several times on the upper surface of the mortar 80 to form the bioglass layer 82, and the floor covering 84 is laid thereon to finish the flooring. Styrofoam having a thickness of about 50 mm is suitable as the heat insulating material 62 used for the above-described floor construction, and coating of bioglass is about 2 to 3 times. When the floor is constructed in this way, when hot water is supplied to the hot water pipe 70, the heat is transferred through the mortar 80 to warm the bioglass layer 82 to release far infrared rays and anions.

In this bio room, the far-infrared rays are emitted from the ceiling by coating the bioglass on the ceiling plate 90. In this case, the bioglass is coated on the surface of the ceiling plate 90 two to three times to form the bioglass layer 92 to complete the ceiling construction.

In the bioroom where bioglass is applied to the walls, floors, and ceilings described above, and far infrared rays and negative ions are emitted therefrom, the benches are arranged by placing the benches 100 in close contact with the walls as shown in FIG. The bathing space is provided so as to lie in the remaining space and absorb far infrared rays and negative ions from the bottom.

Now, the effects of the present invention will be described in detail with reference to the above drawings.

When steam is supplied to the steam pipe 40 fixed to the wall surface of the bioroom, the bioglass coated steel sheet 20 is heated by the heat of steam. Accordingly, the asbestos mesh material 24 attached to the front surface of the bioglass coated steel sheet 20 is heated and far infrared rays and anions are released from the bioglass layer 26 applied thereto.

At the same time, when hot water is supplied to the hot water pipe 70 provided at the bottom, heat is transferred to the mortar 80 and the bioglass layer 82 coated on the upper surface thereof is heated to allow the far infrared rays and negative ions to form the jangpan 84. Will be released through. Therefore, when the bather is lying on the floor, far infrared rays and negative ions are absorbed from the floor through the skin, and the waste accumulated in the body is discharged to the outside along with the sweat.

In addition, since the room is maintained at about 40 to 50 ° C., far infrared rays and anions are emitted by the room temperature even in the bioglass layer 92 coated on the ceiling. In this bio room, far infrared rays and negative ions are radiated to the bather three-dimensionally from the floor, wall, and ceiling.

The steam pipe 40 and the hot water pipe 70 for heating the wall and the bottom of the above-described far infrared rays and anions are emitted from the corresponding bioglass layers 26 and 82 even though high heat is not emitted. This is because the efficiency of far-infrared radiation of bioglass is around 40 ℃, so the wall or floor of this bioroom is kept around 40-50 ℃, so that the user's skin will not be burned even if they touch them. However, since the room temperature is not so high, the bather does not feel frustrated even after long in the room.

The embodiments disclosed herein are only presented by selecting the most preferred examples to help those skilled in the art from the various possible examples, the technical spirit of the present invention is not necessarily limited or limited only by this embodiment, the present invention Various changes and modifications are possible within the scope without departing from the spirit of the invention, as well as other equivalent embodiments.

As described above, the bioroom according to the present invention is coated with bioglass, a new material that emits far infrared rays and anions at low temperatures, on floors, walls, and ceilings, so that it does not cause fatigue or fatigue, even when used for a long time. It also has the advantage of preventing skin damage such as burns due to high heat. In addition, the installation of the bioglass coated steel sheet spaced apart from the wall by a predetermined distance, and heated by the wall heating means on the back to emit far infrared rays and negative ions from the bioglass, simple structure and easy to install and low cost Of course, there is an advantage of easy replacement and repair in case of failure or damage.

In particular, the present invention can independently control the temperature by placing the heating means on the wall and the floor separately, and the far infrared rays and negative ions are radiated from all the surfaces of the interior to be uniformly absorbed in the front of the human body to increase the health and treatment effect. Can be. In addition, not only the steam pipe made of pipes is installed inside the wall, but also the bio glass is formed on the coated plate fixed to the wall, so that it is easy to repair and replace, and when the far-infrared radiation amount is reduced, simply repainting the powdered bio glass It is also easy to maintain as it can recover the original condition.

Claims (6)

A wall heating means installed in the wall to discharge heat; An inner wall coated with bioglass which is heated by the wall heating means and generates far infrared rays and anions; Floor heating means installed on the floor to heat the floor; And A bioroom comprising a bottom coated with an upper surface of the bioglass which is heated by the bottom heating means to generate far infrared rays and anions. According to claim 1, wherein the wall heating means is provided with a steam pipe support member and a steam pipe body which is spaced apart from the wall surface inner surface to the steam pipe support member by a predetermined interval, and the wall surface is interposed between the bio plate The glass room is provided with a glass coated steel plate is spaced apart from the steam pipe and fixed to the front, wherein the bio-glass is characterized by applying the bioglass to the front of the bio-glass coated steel sheet several times. According to claim 2, wherein the wall is laminated with a heat insulating material and a stone in the horizontal direction in order to the inner surface of the brick layer vertically laminated bricks with cement, the inner surface of the tin alternates the steam pipe support member and the coating plate support member Each of the steam pipe and the bioglass coated steel sheets are sequentially arranged at a predetermined interval from the tin, and the bioglass is coated on the inner surface of the bioglass coated steel sheet at least two times. Bio room, characterized in that configured. The method of claim 3, wherein the coating plate support member is a first vertical stiffener fixed in the vertical direction to the tin, and the upper and lower portions of the first vertical stiffener is fixed substantially perpendicular to it and gripping the bioglass coated steel sheet Consists of 1 horizontal reinforcement, The steam pipe support member is spaced apart from the first vertical stiffener by a predetermined interval and is fixed to the upper and lower portions of the second vertical stiffener fixed in a vertical direction to the tin and the second vertical stiffener, and grips the vertical pipe body. Bio room, characterized in that consisting of a second horizontal reinforcement. According to claim 1, wherein the bottom heating means is composed of a hot water pipe, the bottom is laminated with a heat insulating material and a wire mesh sequentially on a concrete floor, and equipped with the hot water pipe thereon and finished flat with mortar, the upper surface The bioroom is characterized by coating the bioglass and then finishing the floor covering. The bioroom of claim 1, further comprising a ceiling plate on which the bioglass is coated at least twice.